DE2619714C2 - - Google Patents

Description

The invention relates to a control device for a AC motor, with a pulse generator connected to the Motor shaft is coupled and depending on the Rotation of the motor shaft provides feedback pulses with a reference signal source for delivering reference signals, which is a desired angular velocity and position the motor shaft, and with a die Feedback pulses and receiving the reference signals Control circuit, which has a time counter and with a manipulated variable corresponding to the phase difference AC motor controls.

Such a control device is essentially made of DE-AS 12 90 623 known. There is the cyclically reset time counter the phase difference between feedback pulses and reference signals determined. U.S. Patent 36 83 345 shows a similar arrangement with free-running time counter.

Furthermore, it is known from DE-OS 20 06 362 Synchronous AC motors with a reference pulse signal to synchronize, namely by comparing the phase this signal with the phase of the revolutions of the Motor wave derived pulse signals, the frequency of which Frequency of the reference signal is the same. The result of this Comparison is used with a direct current alternating current Converter the phase of the AC output voltage To influence motor power supply so that the  Rotation of the motor shaft in synchronism with the phase of the Reference signal is held. Since only the phase of AC voltage can be influenced, this device not to control synchronous AC motors usable.

From Siemens magazine 46 (1972), number 5, pages 335 to 339, is a specific way of forming a Reference signal known. There is a reference frequency from a frequency corresponding to the clock signal and one digital setpoint obtained.

The position of an inverter amplitude is at from the magazine Philips Technische Rundschau, Vol. 33 (1973/74), No. 8, 9, pages 176 to 283 Drive known.

The invention has for its object in a Control device of the type mentioned in one economically a continuous scheme for both the angular velocity and the Phase of the rotational movement of one or more motor shafts create.

According to the invention, this object is achieved with the features of characterizing part of claim 1 solved.

Further developments of the invention result from the Claim 1 subordinate claims.

With the control device according to the invention, a high Achieved precision, so that such controlled motors for the Drive z. B. in papermaking, the closure  and film transport for film cameras as well as synchronized closures in measuring systems are.

Embodiments of the invention are described in more detail with reference to the drawings, the figures of which are listed below.

Fig. 1 shows a block diagram of a first preferred embodiment of the invention,

Fig. 2 is a detailed block diagram of a preferred exemplary example be the main pulse generator, the direction in Fig. 1 shown tax advantage,

Fig. 3 is a block diagram showing a second preferred embodiment of the invention, and

Fig. 4 illustrates the application of the invention for synchronizing the rotation of several AC motors.

In Fig. 1, 11 denotes a main pulse generator with a high degree of frequency stability for generating a reference signal - f _ref - as its output signal, 12 denotes the motor and 13 the motor power supply, which preferably consists of an AC-DC converter with controllable output voltage as well as a DC-AC converter with controllable output frequency and phase. The reference signal f _ref and a motor signal, the frequency f _{mot of which is} proportional to the angular velocity of the motor shaft of the motor 12 , both together are fed to a microprocessor 14 such that a pulse on each of the two signal lines causes an interruption in the program of the microprocessor cause.

The microprocessor must be programmed so that it can perform the following functions:

At any time when a program interruption occurs, the microprocessor will read the time indicated by a digital clock 15 . For each of the two interrupt signals, it will store in its memory a sequence consisting of at least two consecutive times. Based on the two time series, he will calculate the difference in frequency and phase between f _ref and f _mot . Furthermore, the microprocessor will form control signals - preferably sequences of six pulses - for the power supply of the motor 13 , and it will continuously use the estimated differences in frequency and phase between f _ref and f _mot to regulate the control signals of the type that the Frequency ratio and the phase difference are kept constant. For the sake of simplicity of description, it is assumed that the frequency of the signals f _ref and f _{mot are the} same (frequency ratio = 1). It is known that with simple reprogramming the microprocessor can make it possible to change the control function, namely when the frequency ratio can be expressed by a rational number.

A variable circulation speed is easily achieved by changing the frequency f _ref . However, this must follow such that the stability of the frequency and the phase of the reference signal is not endangered. To achieve this, the arrangement of the main generator in the manner shown in FIG. 2 is particularly advantageous. In Fig. 2, a phase-locked oscillator 22 is controlled by a signal f _{c of} a crystal-controlled oscillator 21 and by a signal which is formed by dividing the frequency of the output signal of the phase-locked oscillator by an integer m of a suitable electronic circuit 23 . The value of the integer can be controlled from outside the main generator using well known means. The control of the phase-locked oscillator is achieved in such a way that the frequency of its output signal is maintained from the constant value f _e × n . The frequency of the output signal of the phase-locked oscillator can be divided by a fixed integer m in a suitable circle 24 , e.g. B. to make the value of f _c suitable.

The embodiment shown in Figs. 1 and 2 is particularly advantageous when the invention is used to control a motor located at a considerable distance from the place where the adjustment of the desired rotational speed takes place. In such a case, if the main generator is located where the rotation speed is adjusted and the other circuits are located close to the engine, the reference signal is the only signal to be transmitted between the two parts of the control device. The microprocessor can easily be programmed to check whether the reference signal has not been destroyed by noise. Therefore, it can be transmitted through simple technical means.

In cases other than the foregoing, the embodiment of the invention shown in FIG. 3 can be economically advantageous before.

The difference between the two embodiments of the invention shown in FIGS. 1 and 3 is that in the embodiment shown in FIG. 3 the main generator is replaced by means 38 , namely for supplying the microprocessor with the desired rotational speed in the form of a numerical constants, e.g. B. expresses the number of revolutions per unit of time; these means preferably consist of a suitable number of switches, each with 10 settings, which can be set so that they display this numerical constant, and one of a key, through which an interruption of the program of the microprocessor can then be achieved when a new value of the rotation speed has been selected.

In this case, the microprocessor is to be programmed in such a way that a new speed of rotation can be selected at any time and read by the microprocessor in order to be converted into a corresponding numerical equivalent to 1 / f _ref . At any time when the motor signal causes an interruption in the program of the microprocessor, not only is a number read from the contacts of the encoder 38 , but also a new element is calculated in a sequence of numbers, which are added by adding the numerical equivalent of 1 / f _ref to represent the last element of this series f _ref .

The invention is ideally suited for synchronizing several AC motors, regardless of their location in relation to one another. In this case, the arrangement shown in FIG. 4 is advantageously used.

In Fig. 4 represents 41 a common seed for all control devices Clock. 40 provide joint means for Ver provide information about the desired Umlaufgeschwindig ness either as f _ref or as the number of revolutions per unit time, depending on which of the is Fig. 1 and 3 showed ge preferred embodiments of the invention be utilized. 43 and 43 ' represent the devices mainly shown in FIGS. 1 and 3 but without a digital clock and without means for supplying information about the desired rotational speed, while 42 and 42' represent two of the motors to be synchronized. By using a common digital clock, a common source of information about the desired rotational speed for generating the motor frequency f _mot and the same programs for the microprocessor, it is ensured that the motors are always supplied with energy in such a way that all motor signals are synchronous being held. Therefore, once the desired synchronization has been set, it is maintained as long as the functioning of all elements of the device is maintained. The initial synchronization of the motors can be achieved if necessary by various mechanical or electrical means - z. B. by rotation of the stators or the static parts of those means used for generating the motor signals or by signals to the control device, a number of pulses either from the motor signal or from the reference signal, if any, to be ignored. Other ways of achieving initial synchronization can easily be accomplished by a skilled person.

If a large amount of change in the orbital speed the motor is desired, it is necessary to adjust the output voltage the motor power supply to adapt to the, in the stator Coils of the motor induced electromotive force on the to adjust the desired circulation speed. Even if the Engine is started, it is desirable to supply  Gradually increase tension to get a smooth start of the engine. This problem will be resolved easily with means according to the invention in the following manner solved.

The microprocessor calculates the frequency of the motor signal at all times, ie it calculates a numerical equivalent to the actual speed of rotation. The conversion of the estimated numerical equivalent into the desired supply voltage takes place, preferably by using a digital-to-analog converter 16 or 36 , the AC-DC converter, which is preferably part of the motor power supply.

Control of the motor supply voltage can be further improved to achieve a desired relationship between the speed of the motor and the maximum torque of the motor. This is preferably done by measuring either the alternating current in one of the stator coils of the motor or the intermediate circuit direct current and by converting the measured current into an numerical equivalent using an analog-to-digital converter 17 or 37 . The microprocessor calculates the numerical equivalent of the supply voltage to adapt to the actual rotational speed, taking into account the numerical equivalent of the current in the sense of a subordinate current control. If it is desired for monitoring purposes to represent one or more of the parameters numerically, such as B. the speed of rotation, the motor supply voltage and the motor current, this can easily be achieved in an inexpensive form by providing an appropriate number of output contacts on the micro-processor, to which one or more numerical displays can be connected and via the the microprocessor can deliver one or more numerical equivalents of parameters already in its memory.

However, it must be mentioned that without a special measurement too make the numerical equivalent of the motor supply voltage not the numerical equivalent of what actually exists Is tension, but rather the numerical equivalent of the Setting point of the voltage regulator and therefore in none Way confirms that the desired voltage is actually the existing voltage is. By programming the Microprocessor can display the numerical value shown by any unit of measurement can be expressed. If it comes out economic reasons is desirable, a common Representation to represent more than one parameter by means of selected switching means.

In all embodiments of the invention, the microprocessor must meet the condition that the runtime of the control program is less than the reciprocal of the product of the frequency of the alternating current for feeding the motor and the number of pulse trains for controlling the direct current / alternating current converter the motor power supply - e.g. B. 100 cps and 6 pulses give a maximum runtime:
_^1/6 × 100 s = 16.7 ms.

In the event that it is impossible to complete the term To make the control program short enough, it becomes necessary be some of the control functions through different through distribute control program runs - e.g. B. can in one Run "Upgrading" the numerical Equivalents of the supply voltage take place and in the next Run the result of the current measurement corrected and the digital Analog converters are supplied.

Claims (7)

1. Control device for an AC motor, with a pulse generator, which is coupled to the motor shaft and supplies feedback pulses depending on the rotation of the motor shaft, with a reference signal source for outputting reference signals which indicate a desired angular velocity and position of the motor shaft, and with one Feedback pulses and the reference signals receiving control circuit, which has a time counter and controls the AC motor with a manipulated variable corresponding to the phase difference, characterized in that

• a) the time counter ( 15 ) works without interruption and
• b) the control circuit contains a microprocessor ( 14 ),
  • b1) which receives the feedback pulses (f _mot ), the reference signals (f _ref ) and the time signals from the time counter ( 15 ) and
  • b2) whose program can be interrupted by the feedback pulses (f _mot ) and the reference signals (f _ref ) in order to read the time indicated by the time counter ( 15 ) with each interruption and
  • b3) in order to store a sequence consisting of at least two consecutive times for the feedback pulses and reference signals,
  • b4) the microprocessor ( 14 ), based on the two time sequences, calculating the difference in frequency and phase between the feedback pulses and the reference signals and
  • b5) used to control the motor in such a way that the frequency ratio and the phase difference are kept constant.

2. Control device according to claim 1, characterized in that the reference signal source is arranged outside the microprocessor ( 14 ). 3. Control device according to claim 1, characterized in that the reference signal source is contained in the microprocessor ( 14 ) and the reference frequency is supplied to the microprocessor as a numerical constant. 4. Control device according to one of the preceding claims, characterized in that the microprocessor ( 14 ) has an output for controlling the motor voltage such that it corresponds to the selected speed of the motor. 5. Control device according to one of the preceding claims, characterized in that the microprocessor ( 14 ) has an input for detecting the motor current and influences the output signal for the motor voltage as a function of the motor current. 6. Control device according to one of the preceding claims, characterized in that one or more displays are connected to the microprocessor ( 14 ). 7. Control device for synchronizing several AC motors according to one of the preceding claims, characterized in that for each motor ( 42, 42 ' ) a microprocessor ( 43, 43' ) is provided and that all microprocessors with a common time counter ( 41 ) and a common one Reference signal source ( 40 ) are connected.